This paper develops an ECSM interpretation of gravitational and kinematic time dilation as finite-response reconfiguration burden rather than the slowing of an independently flowing substance called time. Atomic clocks, particle decays, and other timing systems are treated as matter-processes whose internal evolution rate depends on the available reconfiguration capacity of the underlying medium. The paper preserves the standard Lorentz and weak-field gravitational clock factors in the coherent metric limit, while changing their ontology. Gravitational time dilation is interpreted as reduced process-rate freedom in response-loaded medium regions near mass. Kinematic time dilation is interpreted as dynamic reconfiguration burden required to maintain a moving excitation through the medium. Inertia is then identified as resistance to changes in this reconfiguration state. The work builds on previous ECSM papers recovering general relativity as the coherent long-wavelength limit of a finite-response medium and deriving the ECSM coherence parameter from compressible medium dynamics.
Adam Sheldrick (Fri,) studied this question.